yosys/passes/memory/memory_bram.cc

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/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2012 Clifford Wolf <clifford@clifford.at>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
*/
#include "kernel/yosys.h"
USING_YOSYS_NAMESPACE
PRIVATE_NAMESPACE_BEGIN
struct rules_t
{
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struct portinfo_t {
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int group, index, dupidx;
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int wrmode, enable, transp, clocks, clkpol;
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SigBit sig_clock;
SigSpec sig_addr, sig_data, sig_en;
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bool effective_clkpol;
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int mapped_port;
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};
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struct bram_t {
IdString name;
int groups, abits, dbits, init;
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vector<int> ports, wrmode, enable, transp, clocks, clkpol;
vector<portinfo_t> make_portinfos() const
{
vector<portinfo_t> portinfos;
for (int i = 0; i < groups && i < GetSize(ports); i++)
for (int j = 0; j < ports[i]; j++) {
portinfo_t pi;
pi.group = i;
pi.index = j;
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pi.dupidx = 0;
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pi.wrmode = i < GetSize(wrmode) ? wrmode[i] : 0;
pi.enable = i < GetSize(enable) ? enable[i] : 0;
pi.transp = i < GetSize(transp) ? transp[i] : 0;
pi.clocks = i < GetSize(clocks) ? clocks[i] : 0;
pi.clkpol = i < GetSize(clkpol) ? clkpol[i] : 0;
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pi.mapped_port = -1;
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portinfos.push_back(pi);
}
return portinfos;
}
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};
struct match_t {
IdString name;
dict<string, int> min_limits, max_limits;
};
dict<IdString, bram_t> brams;
vector<match_t> matches;
std::ifstream infile;
vector<string> tokens;
int linecount;
string line;
void syntax_error()
{
if (line.empty())
log_error("Unexpected end of rules file in line %d.\n", linecount);
log_error("Syntax error in rules file line %d: %s\n", linecount, line.c_str());
}
bool next_line()
{
linecount++;
tokens.clear();
while (std::getline(infile, line)) {
for (string tok = next_token(line); !tok.empty(); tok = next_token(line)) {
if (tok[0] == '#')
break;
tokens.push_back(tok);
}
if (!tokens.empty())
return true;
}
return false;
}
bool parse_single_int(const char *stmt, int &value)
{
if (GetSize(tokens) == 2 && tokens[0] == stmt) {
value = atoi(tokens[1].c_str());
return true;
}
return false;
}
bool parse_int_vect(const char *stmt, vector<int> &value)
{
if (GetSize(tokens) >= 2 && tokens[0] == stmt) {
value.resize(GetSize(tokens)-1);
for (int i = 1; i < GetSize(tokens); i++)
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value[i-1] = atoi(tokens[i].c_str());
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return true;
}
return false;
}
void parse_bram()
{
if (GetSize(tokens) != 2)
syntax_error();
bram_t data;
data.name = RTLIL::escape_id(tokens[1]);
while (next_line())
{
if (GetSize(tokens) == 1 && tokens[0] == "endbram") {
brams[data.name] = data;
return;
}
if (parse_single_int("groups", data.groups))
continue;
if (parse_single_int("abits", data.abits))
continue;
if (parse_single_int("dbits", data.dbits))
continue;
if (parse_single_int("init", data.init))
continue;
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if (parse_int_vect("ports", data.ports))
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continue;
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if (parse_int_vect("wrmode", data.wrmode))
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continue;
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if (parse_int_vect("enable", data.enable))
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continue;
if (parse_int_vect("transp", data.transp))
continue;
if (parse_int_vect("clocks", data.clocks))
continue;
if (parse_int_vect("clkpol", data.clkpol))
continue;
break;
}
syntax_error();
}
void parse_match()
{
if (GetSize(tokens) != 2)
syntax_error();
match_t data;
data.name = RTLIL::escape_id(tokens[1]);
while (next_line())
{
if (GetSize(tokens) == 1 && tokens[0] == "endmatch") {
matches.push_back(data);
return;
}
if (GetSize(tokens) == 3 && tokens[0] == "min") {
data.min_limits[tokens[1]] = atoi(tokens[2].c_str());
continue;
}
if (GetSize(tokens) == 3 && tokens[0] == "max") {
data.max_limits[tokens[1]] = atoi(tokens[2].c_str());
continue;
}
break;
}
syntax_error();
}
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void parse(string filename)
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{
infile.open(filename);
linecount = 0;
if (infile.fail())
log_error("Can't open rules file `%s'.\n", filename.c_str());
while (next_line())
{
if (tokens[0] == "bram") parse_bram();
else if (tokens[0] == "match") parse_match();
else syntax_error();
}
infile.close();
}
};
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bool replace_cell(Cell *cell, const rules_t::bram_t &bram, const rules_t::match_t&)
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{
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Module *module = cell->module;
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auto portinfos = bram.make_portinfos();
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int dup_count = 1;
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dict<int, pair<SigBit, bool>> clock_domains;
dict<int, bool> clock_polarities;
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pool<int> clocks_wr_ports;
pool<int> clkpol_wr_ports;
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int clocks_max = 0;
int clkpol_max = 0;
clock_polarities[0] = false;
clock_polarities[1] = true;
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for (auto &pi : portinfos) {
if (pi.wrmode) {
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clocks_wr_ports.insert(pi.clocks);
if (pi.clkpol > 1)
clkpol_wr_ports.insert(pi.clkpol);
}
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clocks_max = std::max(clocks_max, pi.clocks);
clkpol_max = std::max(clkpol_max, pi.clkpol);
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}
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log(" Mapping to bram type %s:\n", log_id(bram.name));
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int mem_size = cell->getParam("\\SIZE").as_int();
int mem_abits = cell->getParam("\\ABITS").as_int();
int mem_width = cell->getParam("\\WIDTH").as_int();
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// int mem_offset = cell->getParam("\\OFFSET").as_int();
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int wr_ports = cell->getParam("\\WR_PORTS").as_int();
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auto wr_clken = SigSpec(cell->getParam("\\WR_CLK_ENABLE"));
auto wr_clkpol = SigSpec(cell->getParam("\\WR_CLK_POLARITY"));
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wr_clken.extend_u0(wr_ports);
wr_clkpol.extend_u0(wr_ports);
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SigSpec wr_en = cell->getPort("\\WR_EN");
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SigSpec wr_clk = cell->getPort("\\WR_CLK");
SigSpec wr_data = cell->getPort("\\WR_DATA");
SigSpec wr_addr = cell->getPort("\\WR_ADDR");
int rd_ports = cell->getParam("\\RD_PORTS").as_int();
auto rd_clken = SigSpec(cell->getParam("\\RD_CLK_ENABLE"));
auto rd_clkpol = SigSpec(cell->getParam("\\RD_CLK_POLARITY"));
auto rd_transp = SigSpec(cell->getParam("\\RD_TRANSPARENT"));
rd_clken.extend_u0(rd_ports);
rd_clkpol.extend_u0(rd_ports);
rd_transp.extend_u0(rd_ports);
SigSpec rd_clk = cell->getPort("\\RD_CLK");
SigSpec rd_data = cell->getPort("\\RD_DATA");
SigSpec rd_addr = cell->getPort("\\RD_ADDR");
for (int cell_port_i = 0, bram_port_i = 0; cell_port_i < wr_ports; cell_port_i++)
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{
bool clken = wr_clken[cell_port_i] == State::S1;
auto clkpol = wr_clkpol[cell_port_i] == State::S1;
auto clksig = wr_clk[cell_port_i];
pair<SigBit, bool> clkdom(clksig, clkpol);
if (!clken)
clkdom = pair<SigBit, bool>(State::S1, false);
log(" Write port #%d is in clock domain %s%s.\n",
cell_port_i, clkdom.second ? "" : "!",
clken ? log_signal(clkdom.first) : "~async~");
for (; bram_port_i < GetSize(portinfos); bram_port_i++)
{
auto &pi = portinfos[bram_port_i];
if (pi.wrmode != 1)
skip_bram_wport:
continue;
if (clken) {
if (pi.clocks == 0) {
log(" Bram port %c%d has incompatible clock type.\n", pi.group + 'A', pi.index + 1);
goto skip_bram_wport;
}
if (clock_domains.count(pi.clocks) && clock_domains.at(pi.clocks) != clkdom) {
log(" Bram port %c%d is in a different clock domain.\n", pi.group + 'A', pi.index + 1);
goto skip_bram_wport;
}
if (clock_polarities.count(pi.clkpol) && clock_polarities.at(pi.clkpol) != clkpol) {
log(" Bram port %c%d has incompatible clock polarity.\n", pi.group + 'A', pi.index + 1);
goto skip_bram_wport;
}
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} else {
if (pi.clocks != 0) {
log(" Bram port %c%d has incompatible clock type.\n", pi.group + 'A', pi.index + 1);
goto skip_bram_wport;
}
}
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SigSpec sig_en;
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SigBit last_en_bit = State::S1;
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for (int i = 0; i < mem_width; i++) {
if (pi.enable && i % (bram.dbits / pi.enable) == 0) {
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last_en_bit = wr_en[i + cell_port_i*mem_width];
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sig_en.append(last_en_bit);
}
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if (last_en_bit != wr_en[i + cell_port_i*mem_width]) {
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log(" Bram port %c%d has incompatible enable structure.\n", pi.group + 'A', pi.index + 1);
goto skip_bram_wport;
}
}
log(" Mapped to bram port %c%d.\n", pi.group + 'A', pi.index + 1);
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pi.mapped_port = cell_port_i;
if (clken) {
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clock_domains[pi.clocks] = clkdom;
clock_polarities[pi.clkpol] = clkdom.second;
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pi.sig_clock = clkdom.first;
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pi.effective_clkpol = clkdom.second;
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}
pi.sig_en = sig_en;
pi.sig_addr = wr_addr.extract(cell_port_i*mem_abits, mem_abits);
pi.sig_data = wr_data.extract(cell_port_i*mem_width, mem_width);
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bram_port_i++;
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goto mapped_wr_port;
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}
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log(" Failed to map write port #%d.\n", cell_port_i);
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return false;
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mapped_wr_port:;
}
int grow_read_ports_cursor = -1;
bool try_growing_more_read_ports = false;
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auto backup_clock_domains = clock_domains;
auto backup_clock_polarities = clock_polarities;
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if (0) {
grow_read_ports:;
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vector<rules_t::portinfo_t> new_portinfos;
for (auto &pi : portinfos) {
if (pi.wrmode == 0) {
pi.mapped_port = -1;
pi.sig_clock = SigBit();
pi.sig_addr = SigSpec();
pi.sig_data = SigSpec();
pi.sig_en = SigSpec();
}
new_portinfos.push_back(pi);
if (pi.dupidx == dup_count-1) {
if (pi.clocks && !clocks_wr_ports[pi.clocks])
pi.clocks += clocks_max;
if (pi.clkpol > 1 && !clkpol_wr_ports[pi.clkpol])
pi.clkpol += clkpol_max;
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pi.dupidx++;
new_portinfos.push_back(pi);
}
}
try_growing_more_read_ports = false;
portinfos.swap(new_portinfos);
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clock_domains = backup_clock_domains;
clock_polarities = backup_clock_polarities;
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dup_count++;
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}
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for (int cell_port_i = 0; cell_port_i < rd_ports; cell_port_i++)
{
bool clken = rd_clken[cell_port_i] == State::S1;
auto clkpol = rd_clkpol[cell_port_i] == State::S1;
auto clksig = rd_clk[cell_port_i];
pair<SigBit, bool> clkdom(clksig, clkpol);
if (!clken)
clkdom = pair<SigBit, bool>(State::S1, false);
log(" Read port #%d is in clock domain %s%s.\n",
cell_port_i, clkdom.second ? "" : "!",
clken ? log_signal(clkdom.first) : "~async~");
for (int bram_port_i = 0; bram_port_i < GetSize(portinfos); bram_port_i++)
{
auto &pi = portinfos[bram_port_i];
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if (pi.wrmode != 0 || pi.mapped_port >= 0)
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skip_bram_rport:
continue;
if (clken) {
if (pi.clocks == 0) {
log(" Bram port %c%d.%d has incompatible clock type.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
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goto skip_bram_rport;
}
if (clock_domains.count(pi.clocks) && clock_domains.at(pi.clocks) != clkdom) {
log(" Bram port %c%d.%d is in a different clock domain.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
goto skip_bram_rport;
}
if (clock_polarities.count(pi.clkpol) && clock_polarities.at(pi.clkpol) != clkpol) {
log(" Bram port %c%d.%d has incompatible clock polarity.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
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goto skip_bram_rport;
}
} else {
if (pi.clocks != 0) {
log(" Bram port %c%d.%d has incompatible clock type.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
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goto skip_bram_rport;
}
}
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log(" Mapped to bram port %c%d.%d.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
pi.mapped_port = cell_port_i;
if (clken) {
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clock_domains[pi.clocks] = clkdom;
clock_polarities[pi.clkpol] = clkdom.second;
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pi.sig_clock = clkdom.first;
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pi.effective_clkpol = clkdom.second;
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}
pi.sig_addr = rd_addr.extract(cell_port_i*mem_abits, mem_abits);
pi.sig_data = rd_data.extract(cell_port_i*mem_width, mem_width);
if (grow_read_ports_cursor < cell_port_i) {
grow_read_ports_cursor = cell_port_i;
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try_growing_more_read_ports = true;
}
goto mapped_rd_port;
}
log(" Failed to map read port #%d.\n", cell_port_i);
if (try_growing_more_read_ports) {
log(" Growing more read ports by duplicating bram cells.\n");
goto grow_read_ports;
}
return false;
mapped_rd_port:;
}
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dict<SigSpec, pair<SigSpec, SigSpec>> dout_cache;
for (int grid_d = 0; grid_d*bram.dbits < mem_width; grid_d++)
for (int grid_a = 0; grid_a*(1 << bram.abits) < mem_size; grid_a++)
for (int dupidx = 0; dupidx < dup_count; dupidx++)
{
Cell *c = module->addCell(module->uniquify(stringf("%s.%d.%d.%d", cell->name.c_str(), grid_d, grid_a, dupidx)), bram.name);
log(" Creating %s cell at grid position <%d %d %d>: %s\n", log_id(bram.name), grid_d, grid_a, dupidx, log_id(c));
dict<int, SigBit> clocks;
for (auto &pi : portinfos)
{
if (pi.dupidx != dupidx)
continue;
string prefix = stringf("%c%d", pi.group + 'A', pi.index + 1);
const char *pf = prefix.c_str();
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if (pi.clocks && (!clocks.count(pi.clocks) || pi.sig_clock.wire))
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clocks[pi.clocks] = pi.sig_clock;
SigSpec addr_ok;
if (GetSize(pi.sig_addr) > bram.abits) {
SigSpec extra_addr = pi.sig_addr.extract(bram.abits, GetSize(pi.sig_addr) - bram.abits);
SigSpec extra_addr_sel = SigSpec(grid_a, GetSize(extra_addr));
addr_ok = module->Eq(NEW_ID, extra_addr, extra_addr_sel);
}
if (pi.enable)
{
SigSpec sig_en = pi.sig_en;
sig_en.extend_u0((grid_d+1) * pi.enable);
sig_en = sig_en.extract(grid_d * pi.enable, pi.enable);
if (!addr_ok.empty())
sig_en = module->Mux(NEW_ID, SigSpec(0, GetSize(sig_en)), sig_en, addr_ok);
c->setPort(stringf("\\%sEN", pf), sig_en);
}
SigSpec sig_data = pi.sig_data;
sig_data.extend_u0((grid_d+1) * bram.dbits);
sig_data = sig_data.extract(grid_d * bram.dbits, bram.dbits);
if (pi.wrmode == 1) {
c->setPort(stringf("\\%sDATA", pf), sig_data);
} else {
SigSpec bram_dout = module->addWire(NEW_ID, bram.dbits);
c->setPort(stringf("\\%sDATA", pf), bram_dout);
for (int i = bram.dbits-1; i >= 0; i--)
if (sig_data[i].wire == nullptr) {
sig_data.remove(i);
bram_dout.remove(i);
}
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SigSpec addr_ok_q = addr_ok;
if (pi.clocks && !addr_ok.empty()) {
addr_ok_q = module->addWire(NEW_ID);
module->addDff(NEW_ID, pi.sig_clock, addr_ok, addr_ok_q, pi.effective_clkpol);
}
dout_cache[sig_data].first.append(addr_ok_q);
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dout_cache[sig_data].second.append(bram_dout);
}
SigSpec sig_addr = pi.sig_addr;
sig_addr.extend_u0(bram.abits);
c->setPort(stringf("\\%sADDR", pf), sig_addr);
}
for (auto &it : clocks)
c->setPort(stringf("\\CLK%d", (it.first-1) % clocks_max + 1), it.second);
for (auto &it : clock_polarities)
if (it.first > 1)
c->setParam(stringf("\\CLKPOL%d", (it.first-1) % clkpol_max + 1), it.second);
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}
for (auto &it : dout_cache)
{
if (it.second.first.empty())
{
log_assert(GetSize(it.first) == GetSize(it.second.second));
module->connect(it.first, it.second.second);
}
else
{
log_assert(GetSize(it.first)*GetSize(it.second.first) == GetSize(it.second.second));
module->addPmux(NEW_ID, SigSpec(State::Sx, GetSize(it.first)), it.second.second, it.second.first, it.first);
}
}
module->remove(cell);
return true;
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}
void handle_cell(Cell *cell, const rules_t &rules)
{
log("Processing %s.%s:\n", log_id(cell->module), log_id(cell));
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dict<string, int> match_properties;
match_properties["words"] = cell->getParam("\\SIZE").as_int();
match_properties["abits"] = cell->getParam("\\ABITS").as_int();
match_properties["dbits"] = cell->getParam("\\WIDTH").as_int();
match_properties["wports"] = cell->getParam("\\WR_PORTS").as_int();
match_properties["rports"] = cell->getParam("\\RD_PORTS").as_int();
match_properties["bits"] = match_properties["words"] * match_properties["dbits"];
match_properties["ports"] = match_properties["wports"] + match_properties["rports"];
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log(" Properties:");
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for (auto &it : match_properties)
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log(" %s=%d", it.first.c_str(), it.second);
log("\n");
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pool<IdString> failed_brams;
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for (int i = 0; i < GetSize(rules.matches); i++)
{
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if (!rules.brams.count(rules.matches[i].name))
log_error("No bram description for resource %s found!\n", log_id(rules.matches[i].name));
auto &match = rules.matches.at(i);
auto &bram = rules.brams.at(match.name);
if (match.name.in(failed_brams))
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continue;
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int aover = match_properties["words"] % (1 << bram.abits);
int awaste = aover ? (1 << bram.abits) - aover : 0;
match_properties["awaste"] = awaste;
int dover = match_properties["dbits"] % bram.dbits;
int dwaste = dover ? bram.dbits - dover : 0;
match_properties["dwaste"] = dwaste;
int waste = awaste * bram.dbits + dwaste * (1 << bram.abits) - awaste * dwaste;
match_properties["waste"] = waste;
log(" Wasted bits for bram type %s: awaste=%d dwaste=%d waste=%d\n",
log_id(match.name), awaste, dwaste, waste);
for (auto it : match.min_limits) {
if (!match_properties.count(it.first))
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log_error("Unknown property '%s' in match rule for bram type %s.\n",
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it.first.c_str(), log_id(match.name));
if (match_properties[it.first] >= it.second)
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continue;
log(" Rule #%d for bram type %s rejected: requirement 'min %s %d' not met.\n",
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i, log_id(match.name), it.first.c_str(), it.second);
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goto next_match_rule;
}
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for (auto it : match.max_limits) {
if (!match_properties.count(it.first))
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log_error("Unknown property '%s' in match rule for bram type %s.\n",
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it.first.c_str(), log_id(match.name));
if (match_properties[it.first] <= it.second)
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continue;
log(" Rule #%d for bram type %s rejected: requirement 'max %s %d' not met.\n",
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i, log_id(match.name), it.first.c_str(), it.second);
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goto next_match_rule;
}
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log(" Rule #%d for bram type %s accepted.\n", i, log_id(match.name));
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if (!replace_cell(cell, bram, match)) {
log(" Mapping to bram type %s failed.\n", log_id(match.name));
failed_brams.insert(match.name);
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goto next_match_rule;
}
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return;
next_match_rule:;
}
log(" No acceptable bram resources found.\n");
}
struct MemoryBramPass : public Pass {
MemoryBramPass() : Pass("memory_bram", "map memories to block rams") { }
virtual void help()
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" memory_bram -rules <rule_file> [selection]\n");
log("\n");
log("This pass converts the multi-port $mem memory cells into block ram instances.\n");
log("The given rules file describes the available resources and how they should be\n");
log("used.\n");
log("\n");
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log("The rules file contains a set of block ram description and a sequence of match\n");
log("rules. A block ram description looks like this:\n");
log("\n");
log(" bram RAMB1024X32 # name of BRAM cell\n");
log(" init 1 # set to '1' if BRAM can be initialized\n");
log(" abits 10 # number of address bits\n");
log(" dbits 32 # number of data bits\n");
log(" groups 2 # number of port groups\n");
log(" ports 1 1 # number of ports in each group\n");
log(" wrmode 1 0 # set to '1' if this groups is write ports\n");
log(" enable 4 0 # number of enable bits (for write ports)\n");
log(" transp 0 2 # transparatent (for read ports)\n");
log(" clocks 1 2 # clock configuration\n");
log(" clkpol 2 2 # clock polarity configuration\n");
log(" endbram\n");
log("\n");
log("For the option 'transp' the value 0 means non-transparent, 1 means transparent\n");
log("and a value greater than 1 means configurable. All groups with the same\n");
log("value greater than 1 share the same configuration bit.\n");
log("\n");
log("For the option 'clocks' the value 0 means non-clocked, and a value greater\n");
log("than 0 means clocked. All groups with the same value share the same clock\n");
log("signal.\n");
log("\n");
log("For the option 'clkpol' the value 0 means negative edge, 1 means positive edge\n");
log("and a value greater than 1 means configurable. All groups with the same value\n");
log("greater than 1 share the same configuration bit.\n");
log("\n");
log("A match rule looks like this:\n");
log("\n");
log(" match RAMB1024X32\n");
log(" max waste 16384 # only use this if <= 16384 bram bits are unused\n");
log(" endmatch\n");
log("\n");
log("It is possible to match against the following values with min/max rules:\n");
log("\n");
log(" words .... number of words in memory in design\n");
log(" abits .... number of adress bits on memory in design\n");
log(" dbits .... number of data bits on memory in design\n");
log(" wports ... number of write ports on memory in design\n");
log(" rports ... number of read ports on memory in design\n");
log(" ports .... number of ports on memory in design\n");
log(" bits ..... number of bits in memory in design\n");
log("\n");
log(" awaste ... number of unused address slots for this match\n");
log(" dwaste ... number of unused data bits for this match\n");
log(" waste .... total number of unused bram bits for this match\n");
log("\n");
log("The interface for the created bram instances is dervived from the bram\n");
log("description. Use 'techmap' to convert the created bram instances into\n");
log("instances of the actual bram cells of your target architecture.\n");
log("\n");
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}
virtual void execute(vector<string> args, Design *design)
{
rules_t rules;
log_header("Executing MEMORY_BRAM pass (mapping $mem cells to block memories).\n");
size_t argidx;
for (argidx = 1; argidx < args.size(); argidx++) {
if (args[argidx] == "-rules" && argidx+1 < args.size()) {
rules.parse(args[++argidx]);
continue;
}
break;
}
extra_args(args, argidx, design);
for (auto mod : design->selected_modules())
for (auto cell : mod->selected_cells())
if (cell->type == "$mem")
handle_cell(cell, rules);
}
} MemoryBramPass;
PRIVATE_NAMESPACE_END